Browsing by Author "Oziegbe, O."

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    A Review of Fabrication Techniques and Optimization Strategies for Microbial Biosensors
    (In IOP Conference Series: Earth and Environmental Science (Vol. 1342, No. 1, 2024) Ahuekwe, E. F.; Akinyele, A. F.; Benson, A. E.; Oniha, M. I.; Oziegbe, O.
    optimization of microbial biosensors. More so, the global biosensors market size currently valued at USD25.5 billion in 2021 is expected to grow at a compound annual growth rate (CAGR) of 7.5% to USD36.7 billion in 2026. Microbial biosensors are bioanalytical systems that integrate microorganisms with a physical transducer to generate signals, thus, aiding the identification of analytes. The biosensors are fabricated through a series of steps comprising microbe selection, immobilization onto a matrix, microfabrication, calibration, and validation. The transducers integrated microorganisms generate quantifiable signals, enabling real-time monitoring of a diversity of analytes within food samples. The optimization strategies are scrutinized, with a particular focus on the integration of sundry nanoparticles, such as magnetic, gold, and quantum-dot nanoparticles, which enhance sensor performance. Distinct advantages offered by microbial biosensors promise to revolutionize food quality assessment via cost-effectiveness, rapid sample testing, and the ability to provide access to real-time data. Literature have highlighted certain limitations including interference from complex matrices, instability of microorganisms, and microbial lifespan. In assessing their economic importance, a comparative analysis is presented against conventional food analytical methods like ELISA, PCR, and HPLC; thus, highlighting the unique strengths of microbial biosensors. The future perspectives focus on the potential of the technology in addressing the need for continuous monitoring challenges, and research for further improvements in the biocompatibility of fabrication processes and longterm reusability.
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    Impact of Industrialization on the Environment: Water Quality Index of Pharmaceutical Effluent Discharged in Ota, Ogun State, Nigeria
    (IOP Conf. Series: Earth and Environmental Science, 2025) Nwinyi, Obinna C.; Kayode-Afolayan, S. D.; Ahuekwe, E. F.; Oziegbe, O.; Omonhinmin, Conrad A.
    . There has been an upsurge in the recalcitrance and bioaccumulation of some deterimental pharmaceutical by-products and heavy metals in the aquatic ecosystem. This study determined the water quality index (WQI) of a pharmaceutical effluent discharged in Ota. The physicochemical parameters of the effluent were carried out using turbidimetric (NTU), nephelometric (mg/L), titrimetric (mg/L), conductivity (uS/cm) and spectrophotometric (nm) methods. The parameters assayed include pH, turbidity, conductivity, and temperature. Others include the biochemical oxygen demand (BOD), chemical oxygen demand (COD), biogenic/organic constituents and heavy metals. The physicochemical results obtained were compared with the World Health Organization and United States Environmental Protection Agency standards. These include 4.76±0.07 pH; 1.9±1.00 DO (mg/L) 12.0±1.10 chloride; 3.0±0.03 sulphates; 8.96±0.90 nitrates; 3.21±0.06 phosphates; 29 ±1.12 BOD and 339±2.10 COD. The distribution of heavy metals is in the following order: Zn > Cu > As> Ni> Pb > Cd > Hg. All the results obtained were within acceptable limits of the USEPA and WHO standards. The estimation of the overall quality of the wastewater gave a WQI of 32.54 which suggests a good water quality that is re-usable for irrigation and other purposes.
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    Impact of Industrialization on the Environment: Water Quality Index of Pharmaceutical Effluent Discharged in Ota, Ogun State, Nigeria
    (IOP Conf. Series: Earth and Environmental Science, 2025) Nwinyi, Obinna Chukwuemeka; Kayode-Afolayan, S. D.; Ahuekwe, E. F.; Oziegbe, O.; Omonhinmin, Conrad A.
    There has been an upsurge in the recalcitrance and bioaccumulation of some deterimental pharmaceutical by-products and heavy metals in the aquatic ecosystem. This study determined the water quality index (WQI) of a pharmaceutical effluent discharged in Ota. The physicochemical parameters of the effluent were carried out using turbidimetric (NTU), nephelometric (mg/L), titrimetric (mg/L), conductivity (uS/cm) and spectrophotometric (nm) methods. The parameters assayed include pH, turbidity, conductivity, and temperature. Others include the biochemical oxygen demand (BOD), chemical oxygen demand (COD), biogenic/organic constituents and heavy metals. The physicochemical results obtained were compared with the World Health Organization and United States Environmental Protection Agency standards. These include 4.76±0.07 pH; 1.9±1.00 DO (mg/L) 12.0±1.10 chloride; 3.0±0.03 sulphates; 8.96±0.90 nitrates; 3.21±0.06 phosphates; 29 ±1.12 BOD and 339±2.10 COD. The distribution of heavy metals is in the following order: Zn > Cu > As> Ni> Pb > Cd > Hg. All the results obtained were within acceptable limits of the USEPA and WHO standards. The estimation of the overall quality of the wastewater gave a WQI of 32.54 which suggests a good water quality that is re-usable for irrigation an